Hexapod Rescue Robot

Hexapod-Rescue-Robot

Hexapod Rescue robot is a low-cost, highly-efficient, small robot, using different sensor and smarter algorithm. It can adapt to different kinds of terrains, search and report people in danger of fires, earthquakes, gas leaks, and other situations.
A project I created from October 2015 until now
Received the Toronto Science Fair 2016 Gold Medal and the Life Labs Award

Hexapod Rescue Robot

Introduction:

Nowadays, there are more and more disasters happening every day. Saving people’s lives is certainly the most important thing. The traditional way to rescue by using excavators and shovels is low-efficient, dangerous and not very accurate; it also has a high cost in human resources. As robotics and electronic industries have been well developed today, the artificial intelligent robot can do the job better and quicker, with greater efficiency, shorter time, better accuracy and lower cost. Hexapod Rescue robot is a low-cost, highly-efficient, small robot, using different sensor and smarter algorithm. It can adapt to different kinds of terrains, search and report people in danger of fires, earthquakes, gas leaks, and other situations.

Purpose:

The purpose of the robot is to find possible life signals while moving forwards in complicated terrains. The possibility of life can be ensured by using remote controls and cameras.

Design:

The hexapod is designed to be adapted to different kinds of terrains and also find and investigate life signals efficiently. Hexapod is a simulation of the way insects walk. By using the tripod gait, it can adapt to different uneven terrains better than traditional ways such as wheels and tracks. Hexapod only needs at least 3 points on the ground to be stable, and it can go over rocks and soft, rugged path. This design is still in its early stages, and needs more research development on the algorithms on controlling leg length and moving the center of gravity.
Since there are only a few large and expensive human detectors, this robot collects indirect human signals, such as motion, sound, light, and touch. These possible life signals will be provided to the operators, and they will switch to remote mode to open night vision cameras to investigate the possibility of survivors.

Function:

The hexapod has these several functioning systems:

1.Road detection system: three ultrasonic sensors, two flame sensors

Detect and measure distance to different obstacles, such as flames. It will also choose the path which is least obstructed.

cable.
The power system provides electricity for different systems with different voltage outputs.

Algorithm:

The Algorithm contains two parts: searching (autonomous) mode and remote mode.
In searching mode, the hexapod will move forward based on the terrain and meanwhile search for possible life signals. It will turn or walk around when it detects fire. The light, sound sensor, and button are collecting data all the time. The robot stops every 10 seconds to let motion sensors check if there is movement. If there are any, the data indicates the possibility of a survivor, the robot will send a message to send a notice to the operator, and change into remote mode.
In remote mode, the hexapod will stop moving. The operators can control the robot’s camera on the joystick via wireless communication. If the operators found there are life signals, they could write down the GPS location and report to human rescue forces. Otherwise, the hexapod could switch to searching algorithm/mode when the operator found there are no life signals.
The environmental system (temperature, humidity, and are collecting data and transferring them to operators all the time.
The program is coded in Arduino C in arduino IDE, a language based on C and C++.

Advantage:

The hexapod is really efficient for adapting to different terrains. Hexapod is a simulation of the way insects walk. By using the tripod gait, it can adapt to different uneven terrains better than traditional ways such as wheels and tracks. This is especially useful in the environment after an earthquake. Hexapod only needs at least 3 points on the ground to be stable, and it can go over rocks and soft, rugged paths.
The sensor and video system allows the robot to detect life signals more efficiently. These sensors could detect almost all kinds of human actions. The environmental system could provide environmental data and location for further rescue. The camera and data system could give the operator a brief view about the situation inside. This way of rescuing is really efficient, low-cost, and highly automatic. It could even create a searching network with other robots and human resources, which could make the rescue process faster.

Process of development:

I started the project last November. I planned and bought all the materials I need, and started building the tank and hexapod during the Christmas break. The process of development can be concluded in several stages:

1.Testing and coding individual sensor, then put the sensors in different systems

2.Build and collaborate the tank and hexapod platform (without sensors and microcontroller)

4.Test and code for the hexapod walking algorithm

5.Test and code for communication part, such as camera and remote control

6.Uninstall the sensor system on the tank and put on the hexapod

The advantages of testing each sensor and system separately to lower the possibilities of error while compiling, and make changes quickly.

Future development:

To adapt to more complicated terrains, I will buy stronger and faster servos. I will redesign the hexapod platform with stronger and lighter materials like carbon fibers, due to its heavy weight now. I will add more ultrasonic sensors in the front and underneath to search for possible holes on the ground.
I will also install better battery pack and increase its operating time. A sensor to measure battery level will be added, to transfer battery level to the operator. The sensor part will be all soldered together on PCB board to make the system stabler and smaller.
The communication unit will be improved in case of signal being lost. I will add different units at different channels to make it more reliable.
Because of the complex environment in real situations, I could add a mode when the robot found no way to move. The operator can drive it manually by controlling the joystick.
I could also add a speaker and mic on the robot to let operators talk with the people stuck in the area, the operators could know operator's condition and demands.
A control station is planned to be built, which could display data better and control multiple robots at the same time.